Observation of oscillatory relaxation in the Sn-terminated surface of epitaxial rock-salt SnSe \111\ topological crystalline insulator

Abstract

Topological crystalline insulators have been recently predicted and observed in rock-salt structure SnSe \111\ thin films. Previous studies have suggested that the Se-terminated surface of this thin film with hydrogen passivation, has a reduced surface energy and is thus a preferred configuration. In this paper, synchrotron-based angle-resolved photoemission spectroscopy, along with density functional theory calculations, are used to demonstrate conclusively that a rock-salt SnSe \111\ thin film epitaxially-grown on Bi2Se3 has a stable Sn-terminated surface. These observations are supported by low energy electron diffraction (LEED) intensity-voltage measurements and dynamical LEED calculations, which further show that the Sn-terminated SnSe \111\ thin film has undergone a surface structural relaxation of the interlayer spacing between the Sn and Se atomic planes. In sharp contrast to the Se-terminated counterpart, the observed Dirac surface state in the Sn-terminated SnSe \111\ thin film is shown to yield a high Fermi velocity, 0.50×106m/s, which suggests a potential mechanism of engineering the Dirac surface state of topological materials by tuning the surface configuration.